Image-based global registration system and method applicable to bronchoscopy guidance

ABSTRACT

A global registration system and method identifies bronchoscope position without the need for significant bronchoscope maneuvers, technician intervention, or electromagnetic sensors. Virtual bronchoscopy (VB) renderings of a 3D airway tree are obtained including VB views of branch positions within the airway tree. At least one real bronchoscopic (RB) video frame is received from a bronchoscope inserted into the airway tree. An algorithm according to the invention is executed on a computer to identify the several most likely branch positions having a VB view closest to the received RB view, and the 3D position of the bronchoscope within the airway tree is determined in accordance with the branch position identified in the VB view. The preferred embodiment involves a fast local registration search over all the branches in a global airway-bifurcation search space, with the weighted normalized sum of squares distance metric used for finding the best match.

REFERENCE TO RELATED APPLICATIONS

This application claims priority from U.S. Provisional Patent Application Ser. Nos. 61/299,194, filed Jan. 28, 2010 and 61/300,969, filed Feb. 3, 2010, the entire content of both being incorporated herein by reference.

GOVERNMENT SUPPORT

This invention was made with government support under Grant No. R01-CA074325. awarded by NIH National Cancer Institute. The government has certain rights in the invention.

FIELD OF THE INVENTION

This invention relates generally to bronchoscopy and, in particular, to a global registration system and method useful in image-based bronchoscopy guidance systems and other applications, including other types of endoscopic procedures.

BACKGROUND OF THE INVENTION

Bronchoscopy is a medical procedure commonly used in lung-cancer assessment[1]. Lung-cancer assessment involve two main stages[2,3,4]: 1) three-dimensional (3D) multi-detector computed-tomography (MDCT) image assessment; and 2) live bronchoscopy. During MDCT assessment, the physician uses the two-dimensional (2D) transverse slices obtained from the patient's MDCT scan to identify specific diagnostic regions of interest (ROIs), such as lymph nodes and suspicious nodules[5,6,7]. In this step, the physician also identifies the closest route to each ROI and mentally plans a 3D route using the 2D slices. During bronchoscopy, the physician maneuvers a flexible bronchoscope through the lung airways towards each ROI along the pre-planned mentally defined route. This is done by identifying the bifurcations along the route on the live endoluminal video feed obtained from the bronchoscope. This manually-based route planning procedure proves to be challenging, resulting in errors in bronchoscopy as early as the second airway generation[8,9].

Image-guided bronchoscopy guidance systems enable more accurate bronchoscopy[4,10,11,12,13]. These systems are motivated by virtual bronchoscopy (VB), wherein the 3D MDCT image of a person's chest serves as a “virtual environment”[14,15,16]. A software-defined virtual camera navigates through the lungs in the virtual environment and presents endoluminal renderings of the 3D data, also known as VB images. To facilitate guidance during bronchoscopy, all bronchoscopy guidance systems rely on some method for registration of the real bronchoscope in 3D surgical space to the 3D MDCT virtual space. Based on the type of sensor used for registration, bronchoscopy guidance systems can be either electromagnetic (EM) or image-based[3,4,11,12,13,15,16,17,18].

An EM-based guidance system consists of the following: 1) an EM field generator; 2) a steerable EM probe; and 3) guidance software[12,13,17]. The EM field generator generates an EM field around the patient's chest. The steerable EM probe is inserted through the working channel of the bronchoscope and tracked in the external EM field. Prior to the start of bronchoscopy, the steerable probe is used to calibrate and synchronize the coordinate system of the external EM field and the MDCT coordinate system. Thus, as the EM probe is tracked during bronchoscopy, its position in the MDCT coordinate system becomes nominally known. Such a system allows for immediate establishment of the global position of the bronchoscope tip within the 3D MDCT coordinate system. However, metallic objects in the vicinity induce ferromagnetic device interference, leading to distortions in the external EM field[19]. Moreover, the patient's breathing causes chest movement that leads to registration errors[20]. These errors are magnified in the peripheral airways, as the airway branches become smaller and move with the patient's breathing. Furthermore, once the bronchoscope is guided to the ROI, the steerable probe has to be retracted from the working channel of the bronchoscope so that the biopsy tools can be inserted to collect ROI tissue samples. Thus, EM-based bronchoscopy guidance systems implicitly provide global registration, but suffer in local registration. There has been ongoing research to combine the EM and image-based guidance methods in an attempt to mitigate these problems[21,22].

Image-based bronchoscopy guidance systems rely on volume-rendered[16,23] or surface-rendered[3,4,24,25] endoluminal images of the airway tree from the 3D MDCT scans in order to establish the location of the bronchoscope. This is generally done by comparing the VB images with the real bronchoscopic (RB) video frames. Weighted normalized sum of square difference errors (WNSSD)[24] and normalized mutual information (NMI)[3,4,26] are metrics that are used for comparing the images obtained from the two sources. Registration is carried out using Powell's optimization, simplex or gradient methods. The image-based bronchoscopy guidance methods rely on local registrations at bifurcations and so are less susceptible to patient breathing motion. However, as these methods rely on the bronchoscope video, they are affected by artifacts in bronchoscope video caused by patient coughing or mucous obstruction. Also, most of the available systems rely on manual registration for initialization of the bronchoscope position. During a live bronchoscopic procedure, the absence of a global registration algorithm leads to increased procedure time and some uncertainty in the bronchoscope position. This in turn leads to guidance errors. Thus, image-based bronchoscopy guidance methods implicitly provide excellent local registration, but no global registration.

Global registration is used in various fields such as image fusion[27, 28], remote sensing[29,30], object recognition[31], and robotic navigation[32]. The problem of establishing the global position in robotic navigation is most similar to global registration in the domain of image-based computer-guided bronchoscopy. In robotic navigation, global registration is also referred to as the “robot kidnapping problem,” wherein the position of a robot has to be estimated when it is moved to any arbitrary pose and no motion estimates are available[32]. Moreno et al. presented a non-linear filter, termed evolutive localization filter, that uses raw sensor data and recursively estimates the current pose[32]. Other methods utilizing multi-hypothesis Kalman filters[33, 34], grid-based probabilistic filters[35] and Monte-Carlo localization[36] methods have also been used for addressing the problem of global registration in robot navigation.

In the domain of medical imaging, global registration has been primarily used for multi-modal registration. Zhang et al. have described an adaptive region-intensity-based ultrasound and computed tomography registration[37]. Munim et al. used vector distance functions for registering magnetic resonance (MR) images of multiple patients[38]. Moghari et al. have described a global registration method for aligning multiple bone fractures to a statistical anatomical atlas model[39]. Principal component analysis and the unscented Kalman filter were used for local and global registration, respectively. Fookes et al. have also described a method for registration of multiple MR images from the same patient by formulating the problem as the minimization of a covariance weighted non-linear least square function[40].

In image-based bronchoscopy guidance, researchers have focused on the problem of local registration. However, few have worked on the problem of global registration, whereby the branch location of the bronchoscope is established. Bricault et al. have proposed a multi-level strategy for registration[23]. In this work, the relative position change of the sub-division wall from one bifurcation to the next was used to identify the branch position of the bronchoscope. Shinohara et al. described a branch identification method using eigenspace-image matching[41]. However, this method addresses bronchoscope tracking and cannot be used for global registration. Moreover, it requires manual initialization.

SUMMARY OF THE INVENTION

This invention resides in a global registration system and method useful in image-based bronchoscopy guidance systems and other applications, including other types of endoscopic procedures. Synchronization is restored by identifying the current branch position, thereby facilitating global, technician-independent bronchoscopy guidance without the need for any external device such as an electromagnetic sensor.

Virtual bronchoscopy (VB) renderings of a 3D airway tree are obtained, these including VB views of branch positions within the airway tree. At least one real bronchoscopic (RB) video frame is received from a bronchoscope inserted into the airway tree. An algorithm according to the invention is executed on a computer to identify the several most likely branch positions having a VB view closest to the received RB view, and the 3D position of the bronchoscope within the airway tree is determined in accordance with the branch position identified in the VB view.

The algorithm may use various techniques to speed operation, including an intra-branch search followed by an inter-branch search. In particular, a fast search may be carried out over all the branches in a global airway-bifurcation search space, with a weighted normalized sum of squares distance metric being used to determine the best match. In a preferred embodiment the intra-branch search uses pre-computed lumen region enclosing rectangles in conjunction with a fast local registration refinement.

The intra-branch search is given by:

${\hat{\theta}}^{b_{i}} = {\arg \; {\max\limits_{\chi \in b_{i}}{C\left( {I_{V},I_{CT}^{\chi}} \right)}}}$

where C(•,•) is a similarity function, {circumflex over (θ)}^(b) ^(i) is the optimum view point in branch i for the given RB video frame I_(V) and b_(i) is a subset of K_(tree) and contains all the view points in branch I.

The inter-branch search is given by:

${\hat{\theta}}^{o} = {\arg \; {\min\limits_{\chi \in K_{{\hat{\theta}}^{b_{i}}}}{D\left( {I_{V},I_{CT}^{\chi}} \right)}}}$

where K_({circumflex over (θ)}) ^(b) ^(i) ={{circumflex over (θ)}^(b) ¹ , {circumflex over (θ)}^(b) ² , . . . , {circumflex over (θ)}^(b) ^(n) } is the set of view points obtained from the intra-branch search.

Results show that the algorithm currently needs 3 seconds per search-space branch, with a trend of improving accuracy with reducing search-space being seen. The algorithm gives accuracy rates=90% when using multiple views of the same bifurcation. When using the airway phantom, where a lighting model of the test frames was different from that used for the VB frames, a global registration accuracy of 89% was obtained.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A and 1B show bronchoscopic video frame distortion correction;

FIGS. 2A-2F show examples of the 3D airway tree and the virtual bronchoscope;

FIG. 3 illustrates a pre-computation for intra-branch search;

FIG. 4A shows an input RB frame;

FIGS. 4B-4F show the VB images associated with the best bronchoscope position as found by the intra-branch search in five different branches of the search space;

FIGS. 5A-5E show input bronchoscopic video frames for airway phantom; and

FIGS. 5F-5J show VB images at the bronchoscope position estimated by the algorithm for airway phantom.

DETAILED DESCRIPTION OF THE INVENTION

During bronchoscopy, the physician maneuvers a bronchoscope through the airway tree. An image-based bronchoscopy guidance system provides discrete guidance at bifurcations. In order to register the view seen in the bronchoscope video with multi-detector computed-tomography MDCT co-ordinate system, we model the image seen by the bronchoscope by using 3D MDCT data.

To model the VB views, the bronchoscope camera is first calibrated by using an off-line procedure [42]. Parameters such as the focal length f and the FOV angle of the camera are computed. Coefficients are also found in order to correct the barrel distortion of the video frames as seen in FIG. 1. FIGS. 1A and 1B show bronchoscopic video frame distortion correction. In particular, FIG. 1A shows an example of a bronchoscopic video frame with barrel distortion, and FIG. 1B shows the bronchoscopic video frame after distortion correction.

To create VB views, the airway tree is automatically segmented using a robust segmentation algorithm [43]. The marching cubes algorithm is run on the 3D segmentation to obtain polygonal surface representation of the airway tree [44]. The virtual bronchoscope is designed as a pinhole camera model with a focal length of f and the same image dimensions as the bronchoscope camera. The endoluminal airway surfaces are assumed to be Lambertian, with the light source at the focal point. Secondary reflections are disregarded. Using these assumptions, the VB view is rendered using OpenGL[45] as shown in FIGS. 2A-2F. Virtual bronchoscopic views. FIGS. 2A-2C show examples of the 3D airway tree and the virtual bronchoscope (yellow cylinder+graphical needle) positioned within the trachea, left main bronchus and the right main bronchus (shown in FIGS. 2D-2F) and the corresponding VB views.

The Global Registration Problem

Global registration can be defined as establishing the current branch position of the bronchoscope in the 3D airway tree. To formulate the global registration problem, we consider the scenario where the bronchoscope is “blindly” inserted into the airway so that it lies at some bifurcation. We denote the real bronchoscopic (RB) video frame from the bronchoscope as I_(V)(x, v). The virtual bronchoscopy (VB) renderings obtained from the virtual bronchoscope are denoted by I_(CT)(x, y). The current unknown viewpoint of the bronchoscope is denoted by θ=(x, y, z, α, β, γ), where (x, y, z) gives the 3D spatial position and (α, β, γ) specifies the Euler angles. The global registration algorithm finds the branch that contains the viewpoint with a VB view closest to the given RB view.

This problem can be posed as a Maximum A Posteriori (MAP) problem. The first part is probability density estimation problem, where we estimate the posterior density over the space of available bronchoscope poses given the incoming bronchoscopic video. This problem formulation is similar to that by Moreno et al [32]. In that paper, an iterative solution is used for global registration but we present a method for registration using a single frame which is similar to the method by Wei β et al [46]. From MAP point of view, the global registration problem is an optimization problem where we estimate the branch in which the bronchoscope gives a pose that maximizes the posteriori probability density

$\begin{matrix} {\hat{\theta} = {\arg \; {\max\limits_{\chi \in K_{tree}}{p\left( \chi \middle| I_{V} \right)}}}} & (1) \end{matrix}$

where {circumflex over (θ)} is the estimated optimum view point, χ is one of the view points in K_(tree), the search space for the view points and p(χ|I_(V)) is the posterior density over the space of available bronchoscope poses given the incoming bronchoscopic video. Using Bayes theorem, we get

$\begin{matrix} {{p\left( \chi \middle| I_{V} \right)} = \frac{{p\left( I_{V} \middle| \chi \right)} \cdot {p(\chi)}}{p\left( I_{V} \right)}} & (2) \end{matrix}$

In the above expression, if all bronchoscope poses are considered equi-likely p(χ) can be considered as a constant and p(I_(V)) is a constant with respect to χ. Thus, we get

argmax p(χ|I _(V))=argmax p(I _(V)|χ)  (3)

The term p(I_(V)|χ) can be estimated using a similarity function that finds the similarity between I_(V) and the VB image rendered at χ, given by I_(CT) ^(χ). Hence, (3) becomes

argmax p(I _(V)|χ)=argmax C(I _(V) ,I _(CT) ^(χ))  (4)

where C(•,•) is a similarity function that gives the measure of similarity between the bronchoscopic video frame I_(V) and I_(CT) ^(χ) the rendering obtained at pose χ. If the similarity function C(•,•) is replaced by a dissimilarity measure, the global registration problem becomes

$\begin{matrix} {\hat{\theta} = {\arg \; {\min\limits_{\chi \in K_{tree}}{D\left( {I_{V},I_{CT}^{\chi}} \right)}}}} & (5) \end{matrix}$

here D(•,•) is a dissimilarity function between the RB image I_(V) and the VB view I_(CT) ^(χ) at view point χ and K_(tree) is the search space for the view points. The optimum branch is given by

b ^(o) =B({circumflex over (θ)})  (6)

where B(•) is a function that finds the branch containing the view point {circumflex over (θ)}.

The proposed algorithm accepts as input one or more live bronchoscopic video frames and outputs the 3D position of the bronchoscope within the airway tree. The algorithm is invoked during live bronchoscopy when the position of the bronchoscope is unknown. The algorithm will then determine the bronchoscope position within the airway tree. Before invoking the algorithm, the physician positions the bronchoscope to give a good view of an airway bifurcation, so that the lumen region is well represented, as shown in FIG. 4. Multiple runs of the algorithm on either the same bifurcation or at related bifurcations (parent-daughter branches) can be used to improve the overall accuracy of the method. The algorithm broadly divides into two major stages: intra-branch search and inter-branch search.

FIG. 3 illustrates a pre-computation for intra-branch search. This figure shows the pre-computation carried out for the branch highlighted by the blue line. The red lines are the pre-defined centerline navigation routes through the 3D airway tree. The green triangles highlight three of the pre-defined view-sites (A, B, C) along the selected branch. The figures to the right of the view-sites are the VB renderings (A1, B1, C1), the lumen thresholded images (A2, B2, C2) and the minimum enclosing rectangles (A3, B3, C3) associated with the respective view-sites. The longer length of the minimum enclosing rectangle is saved during pre-computation and later used for localizing the position of the given RB frame in a given branch.

Intra-Branch Search

The intra-branch search is formulated as

$\begin{matrix} {{\hat{\theta}}^{b_{i}} = {\arg \; {\max\limits_{\chi \in b_{i}}{C\left( {I_{V},I_{CT}^{\chi}} \right)}}}} & (7) \end{matrix}$

where C(•,•) is a similarity function, {circumflex over (θ)}^(b) ^(i) is the optimum view point in branch i for the given RB video frame I_(V) and b_(i) is a subset of K_(tree) and contains all the view points in branch i.

This optimization process needs spanning through all possible view positions in a given branch. This is not practical in a real-time algorithm due to the excessive time involved. Hence, we use a novel intra-branch search which comprises of two steps. In the first step, the intra-branch search carries out a fast scan through all the pre-defined view sites along the centreline of the branch. The second step comprises render position adjustment using fast local registration. Because of uncertainty in the roll angle of the bronchoscope we use a set of four likely positions for each branch using different roll angles.

The minimum enclosing rectangle of the lumen region has a change in its larger dimension as the render position moves along the centreline towards the bifurcation as shown in FIG. 3. This is the underlying idea of the fast-scan search along the centreline. In this search, first the input real image I_(V) is thresholded to segment out the lumen region. The p-tile thresholding with a value of p=10 has been empirically found to give good results for segmenting out the lumen. Once the lumen region is segmented, the convex hull of the segmented region is found. We use the Bentley-Faust-Preparata (BFP) fast approximate 2D convex hull algorithm for this purpose [47]. This convex hull is used to find the minimum enclosing rectangle of the lumen region as shown in FIG. 3. The larger dimension of the enclosing rectangle is saved as Dim_(Max). The same feature extraction step is carried out at all the pre-defined centreline view points of all the branches as a pre-computation step and the larger dimension of the enclosing rectangle is saved. During live global registration, the intra-branch search gives the best centreline view-point at each branch that has its feature value closest to Dim_(Max). The best rendering position that is obtained has a fixed roll angle. However, the real image could have any possible roll angle. To address this, roll angles of 90 degrees, 180 degrees and 270 degrees are applied to this rendering position resulting in the four best rendering positions for each branch.

The real image is obtained from a bronchoscope having multiple degrees of freedom. So the four best rendering positions obtained in the previous step may not give rendering images I_(CT) similar to the real image I_(V). Therefore, the four rendering positions obtained from the previous step are adjusted further using the inverse compositional method for local registration [24]. The local registration uses WNSSD metric for image comparison and the optimal Gauss-Newton gradient for parameter update (Θ_(Δ)) as given in (8) and (9).

$\begin{matrix} {D_{1} = \left\{ {\sum\limits_{u,v}{w_{u,v}\left\lbrack {\frac{{I_{CT}\left( {u,v} \right)} - \mu_{CT}}{\sigma_{CT}} - \frac{{I_{V}\left( {u,v} \right)} - \mu_{V}}{\sigma_{V}\;}} \right\rbrack}^{2}} \right\}} & (8) \end{matrix}$

where μ_(CT) and μ_(V) are the respective weighted-image means and θ_(CT) ² and σ_(V) ² are the respective weighted image variances and w_(u,v) are weights that can be used to arbitrarily assign higher importance to pixels in the image based on geometry, graylevel value, gradient strength, or any appropriate confidence measure. Here, we use the trivially weighted case

$\begin{matrix} {\mspace{79mu} {{{{w_{u,v} = 1},{\forall u},v}\Theta_{\Delta}} = \left. H^{- 1} \middle| {}_{\Theta = \overset{\rightarrow}{0}}{\sum\limits_{u,v}{w_{u,v}{{\overset{\_}{\left\lbrack \frac{\partial I_{CT}}{\partial\Theta} \right\rbrack}}_{\Theta = \overset{\rightarrow}{0}}^{T}\begin{bmatrix} {{{\overset{\_}{I}}_{V}\left( {W\left( {u,v,{Z;\Theta_{eq}}} \right)} \right)} -} \\ {{\overset{\_}{I}}_{CT}\left( {u,v} \right)} \end{bmatrix}}}} \right.}} & (9) \end{matrix}$

where

${\overset{\_}{\left\lbrack \frac{\partial I_{V}}{\partial\Theta} \right\rbrack}}_{\Theta}$

is a 6D row vector of steepest-descent images, Ī_(V)(W(u,v,Z;Θ_(eq))) and Ī_(CT)(u,v) are the normalized images and H, the Gauss-Newton Hessian is computed as

$\begin{matrix} {H = {\sum\limits_{u,v}{w_{u,v}{\overset{\_}{\left\lbrack \frac{\partial I_{V}}{\partial\Theta} \right\rbrack}}^{T}\overset{\_}{\left\lbrack \frac{\partial I_{V}}{\partial\Theta} \right\rbrack}}}} & (10) \end{matrix}$

Parameter update is run for 200 ms, which is sufficient for convergence and limits the total run-time of the algorithm resulting in four image rendering positions for each branch. The rendered images at each of these positions are thresholded to obtain the lumen region. These thresholded images are then compared with the lumen thresholded image obtained from the real image using the metric C₁ described in equation (11). Substituting from equation (11) in equation (7) we get the best rendering position of the branch.

$\begin{matrix} {{{C_{1}\left( {I_{1},I_{2}} \right)} = \frac{n_{I_{1}\bigcap I_{2}}}{n_{I_{1}\bigcup I_{2}}}}{where}{n_{I_{1}\bigcap I_{2}} = \left\{ {{\begin{matrix} 1 & {{{if}\mspace{14mu} {I_{1}\left( {u,v} \right)}} > {0\mspace{14mu} {and}\mspace{14mu} {I_{2}\left( {u,v} \right)}} > 0} \\ 0 & {otherwise} \end{matrix}{and}n_{I_{1}\bigcup I_{2}}} = \left\{ \begin{matrix} 1 & {{{if}\mspace{14mu} {I_{1}\left( {u,v} \right)}} > {0\mspace{14mu} {or}\mspace{14mu} {I_{2}\left( {u,v} \right)}} > 0} \\ 0 & {otherwise} \end{matrix} \right.} \right.}} & (11) \end{matrix}$

Inter-Branch Search

The inter-branch search is given by

$\begin{matrix} {{\hat{\theta}}^{o} = {\arg \; {\min\limits_{\chi \; \in K_{{\hat{\theta}}^{b_{i}}}}{D\left( {I_{V},I_{CT}^{\chi}} \right)}}}} & (12) \end{matrix}$

where K_({circumflex over (θ)}) ^(b) ^(i) ={{circumflex over (θ)}^(b) ¹ , {circumflex over (θ)}^(b) ² , . . . , {circumflex over (θ)}^(b) ^(n) } is the set of view points obtained from the intra-branch search. In (12) we use the WNSSD dissimilarity metric as defined in equation (8). The optimum view point is used to find the current bronchoscope branch position using equation (6).

The above global registration method has been summarized in equation (12). FIGS. 4A-4F show the best matches for the different branches of the search space and FIG. 4B, the correctly identified branch after the inter-branch search. FIG. 4A shows the input RB frame and FIGS. 4B-4F show the VB images associated with the best bronchoscope position as found by the intra-branch search in five different branches of the search space. Inter-branch search correctly identified branch with rendering shown in FIG. 4B as the best branch.

Algorithm 1: Pre-computation Phase: Computation of the feature value for every view site along each branch. Initialization: Computing features for every view-site along a branch for ∀ branch i ε search-space do  for ∀ view-site j ε branch i do   Generate a virtual image I_(CT).   Threshold the image I_(CT) using p-tile thresholding (p = 10).   Use BFP algorithm to find the convex hull of the thresholded lumen   region.   Find the minimum enclosing rectangle using the convex hull.    save the longer dimension of the rectangle by the view-site index j.  end end

Algorithm 2: Global Registration for each new real image I_(V) do  Capture real image I_(V) into buffer  Threshold the real image I_(V)  Find convex hull of the thresholded region  Find minimum enclosing rectangle using the convex hull  Set bestValue=∞ and bestBranch=0  for every branch i in the search-space do   Find closest branch view-site j using the pre-computed features for   branch i   From view-site j, obtain 4 viewing positions ( roll angles of   θ = [90, 180, 270] ).   Use (11) to find the VB image at the best render position for the   branch I_(CT) ^(θ) ^(b) ₁   Use (8) to find D₁(i) ( I_(CT) = I_(CT) ^(θ) ^(b) ₁ ).   if D₁(i) ≦ bv then    bestValue = D₁(i)    bestBranch = i   end  end end

Results

To evaluate the accuracy of the global registration algorithm, we carried out three sets of tests. In the first set, we evaluated the global registration algorithm using virtual case studies. The second set of tests evaluated the accuracy of the global registration algorithm using RB frames obtained from the bronchoscopic exploration of an airway phantom. In the third set, we evaluated the improvement in the accuracy of the algorithm when multiple test frames were used.

Evaluation Using Virtual Cases

The global registration algorithm was evaluated using the three virtual cases derived from the CT data of consented patients as described in Table I. While using virtual bronchoscopic cases, a minimum of 28 branches from the first five airway generations were used. Four different tests were carried out by varying the search-space of the algorithm. In all tests, a virtual bronchoscopic bifurcation view was randomly selected from the branch search space—this served as the unknown “live bronchoscope video” view in the test. This bifurcation view was obtained by randomly moving to any of the view sites along a branch. A random roll angle from 0-360 degrees was used and a perturbation of up to ±5 mm was applied to the virtual bronchoscopic position to move the virtual bronchoscope off the center line. In the first test set, all branches were used for the search space. In the second set, the search space was divided into two by using branches either in the left lung or right lung only. In the third set, the search space was divided into five different parts based on the lung lobar regions. In the fourth set, only branches that were daughters of the same branch were used in the search space. The results of these tests are summarized in Table II. Global registration accuracy ranged from 71% to 92%. Note that a random selection from among 28 airway branches would only give an “accuracy” of 3.6%.

TABLE I Summary of cases used for testing. (Δ_(X), Δ_(Y)) in Total Total Case number Scanner mm slices branches 20349.3.47 Siemens Sensation 16 (0.55, 0.55) 517 227 20349.3.49 Siemens Sensation 40 (0.64, 0.64) 673 273 20349.3.61 Siemens Sensation 40 (0.6, 0.6) 588 219

TABLE II Global registration accuracy in percent for different test sets for virtual bronchoscopic cases. Case Full-tree Half-tree Lobar Branch pairs number (set 1) (set 2) (set 3) (set 4) 47 73% 76% 80% 92% 49 75% 77% 83% 91% 61 71% 73% 80% 83% Evaluation using a Phantom Case

The airway phantom test involved live bronchoscopy on a preconstructed airway-tree phantom [25]. The phantom consists of 5 different accessible branch bifurcations when using a 5.9 mm diameter bronchoscope. While carrying out the global registration, each incoming video frame from the bronchoscope was used as input and the output of the global-registration algorithm was one of the five branches from the search space. In order to carry out the tests, the bronchoscope was moved to each of the five different branches and the video collected from this bronchoscope maneuver was used in the testing. From the collected video, only those frames that gave good bifurcation views were used in the study. A total of 836 such frames were obtained. The global registration algorithm gave an accuracy of 89% for the 836 frames (see FIG. 5A-5J). FIGS. 5A-5J show global registration results for airway phantom. The top row (FIGS. 5A-5E) are the input bronchoscopic video frames and the bottom row (FIGS. 5F-5J) are the VB images at the bronchoscope position estimated by the algorithm.

Evaluation Using Multiple Frames

To evaluate the performance of the global registration algorithm using multiple frames, the virtual cases described in Table I were used. This test setup was the same as that used for evaluation using virtual cases. We carried out two sets of tests. In the first set, multiple “random views” of the same bifurcation were used for testing. In this testing methodology, each of the frames was independently evaluated by the global registration algorithm. The frame that gave the lowest WNSSD metric (bestValue from (12)) decided the branch location for the frames. In the second set, test frames from two consecutive bifurcations were used. Both the branches were independently evaluated. Of the two test frames, the frame giving the lower WNSSD metric determined the branch pair. The results for this set of testing has been summarized in Table III. The global registration accuracy ranges from 82% to 99%. In all of the above tests, the algorithm was found to run in an average time of 2-3 seconds per search space branch.

TABLE III Global registration accuracy in percent when using multiple test frames for virtual bronchoscopic cases. Two consecutive Case 3 frame 5 frame bifurcations number (set 1) (set 1) (set 2) 47 94% 98% 89% 49 95% 99% 87% 61 85% 86% 82%

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1. A global registration method useful in bronchoscopic guidance and other applications, the method comprising the steps of: obtaining virtual bronchoscopy (VB) renderings of a 3D airway tree, the renderings including VB views of branch positions within the airway tree; receiving at least one real bronchoscopic (RB) view from a bronchoscope inserted into the airway tree; providing and executing an algorithm on a computer operative to identify the optimum branch position having a VB view closest to the received RB view; and outputting the 3D position of the bronchoscope within the airway tree based upon the branch position identified in the VB view.
 2. The method of claim 1, wherein the RB view is derived from a video frame.
 3. The method of claim 1, wherein the algorithm identifies a plurality of most likely branch positions having VB views closest to the received RB view.
 4. The method of claim 1, wherein the algorithm uses domain-specific information regarding general bronchoscope position within the airway tree.
 5. The method of claim 4, wherein the domain-specific information includes current lung designation or lung lobar position.
 6. The method of claim 1, including the steps of: receiving a plurality of RB views from the bronchoscope; and identifying the optimum branch position having a VB view closest to the RB views.
 7. The method of claim 6, wherein the multiple RB views are associated with the same or multiple branch positions within an airway tree.
 8. The method of claim 1, wherein the algorithm includes the step of performing a fast search over all the branches in a global airway-bifurcation search space using a weighted normalized sum of squares distance metric to determine the best match.
 9. The method of claim 1, wherein the algorithm performs an intra-branch search followed by an inter-branch search.
 10. The method of claim 9, wherein the intra-branch search is given by: ${\hat{\theta}}^{b_{i}} = {\arg \; {\max\limits_{\chi \in b_{i}}{C\left( {I_{V},I_{CT}^{\chi}} \right)}}}$ where C(•,•) is a similarity function, {circumflex over (θ)}^(b) ^(i) is the optimum view point in branch i for the Oven RB video frame I_(V) and b is a subset of K_(tree) and contains all the view points in branch I; and the inter-branch search is given by: ${\hat{\theta}}^{o} = {\arg \; {\min\limits_{\chi \in K_{{\hat{\theta}}^{b_{i}}}}{D\left( {I_{V},I_{CT}^{\chi}} \right)}}}$ where K_({circumflex over (θ)}) ^(b) ^(i) ={{circumflex over (θ)}^(b) ¹ , {circumflex over (θ)}^(b) ² , . . . , {circumflex over (θ)}^(b) ^(n) } is the set of view points obtained from the intra-branch search.
 11. The method of claim 9, wherein the intra-branch search uses pre-computed lumen region enclosing rectangles and a fast local registration refinement.
 12. A global registration method useful in bronchoscopic guidance and other applications, the method comprising the steps of: obtaining virtual bronchoscopy (VB) renderings of a 3D airway tree, the renderings including VB views of branch positions within the airway tree; receiving at least one real bronchoscopic (RB) video frame from a bronchoscope inserted into the airway tree; providing and executing an algorithm on a computer to identify branch positions having VB views closest to the received RB video frame, the algorithm including an intra-branch search followed by an inter-branch search; and outputting the 3D position of the bronchoscope within the airway tree based upon the most likely branch position identified in the VB view.
 13. The method of claim 12, wherein the algorithm uses domain-specific information regarding general bronchoscope position within the airway tree.
 14. The method of claim 13, wherein the domain-specific information includes current lung designation or lung lobar position.
 15. The method of claim 12, wherein the algorithm includes the step of performing a fast search over all the branches in a global airway-bifurcation search space using a weighted normalized sum of squares distance metric to determine the best match.
 16. The method of claim 12, wherein the intra-branch search is given by: ${\hat{\theta}}^{b_{i}} = {\arg \; {\max\limits_{\chi \in b_{i}}{C\left( {I_{V},I_{CT}^{\chi}} \right)}}}$ where C(•,•) is a similarity function, {circumflex over (θ)}^(b) ^(i) is the optimum view point in branch i for the given RB video frame I_(V) and b_(i) is a subset of K_(tree) and contains all the view points in branch I; and the inter-branch search is given by: ${\hat{\theta}}^{o} = {\arg \; {\min\limits_{\chi \in K_{{\hat{\theta}}^{b_{i}}}}{D\left( {I_{V},I_{CT}^{\chi}} \right)}}}$ where K_({circumflex over (θ)}) ^(b) ^(i) ={{circumflex over (θ)}^(b) ¹ , {circumflex over (θ)}^(b) ² , . . . , {circumflex over (θ)}^(b) ^(n) } is the set of view points obtained from the intra-branch search.
 17. The method of claim 12, wherein the intra-branch search uses pre-computed lumen region enclosing rectangles and a fast local registration refinement.
 18. A global registration system useful in bronchoscopic guidance and other applications, comprising: a memory storing virtual bronchoscopy (VB) renderings of a 3D airway tree, the renderings including VB views of branch positions within the airway tree; a bronchoscope generating a real bronchoscopic (RB) view of the airway tree; a computer operative to use the RB view to search and analyze the VB renderings to identify the branch position that most closely matches the received RB view; and a display presenting the 3D position of the bronchoscope within the airway tree based upon the branch position identified in the VB view.
 19. The system of claim 18, wherein the bronchoscopic outputs the RB view in the form of one or more video frames.
 20. The system of claim 18, wherein the computer is operative to identify a plurality of most likely branch positions having VB views closest to the received RB view.
 21. The system of claim 18, wherein the computer uses domain-specific information regarding general bronchoscope position within the airway tree.
 22. The system of claim 21, wherein the domain-specific information includes current lung designation or lung lobar position.
 23. The system of claim 18, wherein: the bronchoscope generates a plurality of RB views; and the computer is operative to identify an optimum branch position having a VB view closest to the RB views.
 24. The system of claim 23, wherein the multiple RB views are associated with the same or multiple branch positions within an airway tree.
 25. The system of claim 18, wherein the computer performs a fast search over all the branches in a global airway-bifurcation search space using a weighted normalized sum of squares distance metric to determine the best match.
 26. The system of claim 18, wherein the computer performs an intra-branch search followed by an inter-branch search.
 27. The system of claim 26, wherein the intra-branch search is given by: ${\hat{\theta}}^{b_{i}} = {\arg \; {\max\limits_{\chi \in b_{i}}{C\left( {I_{V},I_{CT}^{\chi}} \right)}}}$ where C(•,•) is a similarity function, θ^(b) ^(i) is the optimum view point in branch i for the given RB video frame I_(V) and b_(i) is a subset of K_(tree) contains all the view points in branch and the inter-branch search is given by: ${\hat{\theta}}^{o} = {\arg \; {\min\limits_{\chi \in K_{{\hat{\theta}}^{b_{i}}}}{D\left( {I_{V},I_{CT}^{\chi}} \right)}}}$ where K_({circumflex over (θ)}) ^(b) ^(i) ={{circumflex over (θ)}^(b) ¹ , {circumflex over (θ)}^(b) ² , . . . , {circumflex over (θ)}^(b) ^(n) } is the set of view points obtained from the intra-branch search.
 28. The system of claim 26, wherein the intra-branch search uses pre-computed lumen region enclosing rectangles and a fast local registration refinement. 